DE60112839T2 - Printing plate, process for its production, process for its reuse and printing machine - Google Patents

Description

BACKGROUND OF THE INVENTION:

Field of the invention:

The The present invention relates to a printing plate, a method for Production of a printing plate, a reuse method for the printing plate and a printing press. More specifically, the present invention relates Method for producing and reusing a printing plate, on which a picture is recorded based on digital data, and a printing machine using such a printing plate becomes.

Description of the state of the technique:

In Recently, in general printing processes, numerous printing steps have been made digitized. That is, image data is generated by generating a Image or text using, for example, a PC or digitized by screening an image using a scanner, and a printing plate is produced directly on the basis of the digital data. That way you can Improve the printing workflow and shorten the entire printing process and the execution a high picture quality has been simplified.

In a conventional one Printing process has been generally called a PS plate (i.e. a presensitized plate). The PS plate usually closes a hydrophilic non-image area made of anodized alumina and a hydrophobic image area formed on the surface of the hydrophilic non-image area by curing a photosensitive Resin is produced. For producing a printing plate under However, using the PS disk is a variety of steps required, and therefore it is expensive and time-consuming, such Plate manufacture. As a result, it's not easy for the whole Reduce the printing time required and reduce the cost of doing so. This is one of the main factors that cost the printed Increase materials, especially in short-term printing. Furthermore, in cases in which a PS plate is used requires a development step, in which a developer is used and therefore this is not just a time-consuming process, but also raises in terms of avoidance of environmental pollution, that the developer waste has to be treated.

As well becomes common a method for producing the PS plate is applied, wherein a Film containing punched out information of an original image, with contacted a printing plate and subjected to exposure to light and this production of the printing plate is one of the obstacles the generation of a disk directly from digital data and the Digitization of the printing process prevented. In addition, must in a conventional Procedure a printing plate replaced by a new one after a printing activity the used plate should be disposed of.

It There are some commercial procedures that are under consideration the above-mentioned disadvantage of using the PS plate the digitized Correspond printing method and wherein the development process omitted can be. For example, Japanese Unexamined Patent Application Publication JP-A-63-102936 a production process wherein ink which is a photosensitive Contains resin, for one liquid inkjet Printer is used, which is injected onto a printing plate material and wherein the image area formed by the ink through a photo irradiation process hardened becomes. Further, Japanese Unexamined Patent Application JP-A-11-254633 a method wherein a color offset printing plate is produced using an ink jet head ejecting a solid ink.

Furthermore For example, a method is known in which a printing plate is produced by sequentially applying a laser absorption layer Carbon black and a silicone resin layer on a PET (polyethylene terephthalate) film, and heating the laser absorbing layer by recording an image using laser beams so that the silicone resin of the Laser ablation is subjected. Likewise, another procedure in which a printing plate is made by sequential Applying a lipophilic laser absorbing layer and a hydrophilic layer on an aluminum plate and subjecting the hydrophilic Layer of a laser ablation in the same manner as above Use of laser beams.

Further, there has been proposed a method wherein a hydrophilic polymer is used as a recording medium and a plate is prepared by converting an irradiated area by optical image processing to become lipophilic. Although it may be possible to make a disk directly from digital data, however, in the application of the above methods, the disk must be printed after printing It will be replaced by a new one so that the next printing can be started, and consequently, also in this process, the used plate becomes waste.

SUMMARY OF THE INVENTION:

consequently is an inventive Aim to provide a reusable pressure plate and a Method for producing a reusable printing plate, which can be imaged directly on the basis of digital data and a high picture quality without chemical development. Another object of the invention is the provision of a method for reusing a such pressure plate, so that the plate can be used repeatedly can. A still further object of the invention is to provide a printing press, the use of such a printing plate be able to.

According to the invention provided a printing plate having a hydrophilic surface of a Plate containing a photocatalyst and a hydrophobic image area, which contains an organic compound which is based on at least one Part of the hydrophilic surface is present, wherein the organic compound by the irradiation of light with a higher Energy as the band gap energy of the photocatalyst is decomposed and removed.

According to one further inventive Aspect, the photocatalyst is a titania photocatalyst.

According to one still further inventive Aspect, the hydrophobic image area is prepared by release an inky liquid, containing the organic compound on the hydrophilic surface of the Printing plate using an image forming ink jet device.

According to one still further inventive Aspect, the hydrophobic image area is made by transfer an ink-like material containing the organic compound the hydrophilic surface the printing plate using a film on which the ink-like Material containing the organic compound has been applied, and a transmission device.

According to still another inventive Aspect, the organic compound is an organotitanium compound.

According to still another inventive Aspect, the organic compound is an organosilicon compound.

According to still Another developmental aspect is the organic one Compound a fatty acid extrin.

According to the invention further provided a method for producing a printing plate, that the generation of a hydrophobic image area on at least a part of a hydrophilic surface of a plate containing a Contains photocatalyst, wherein the hydrophobic image area using an organic Compound is formed when irradiated with light higher Energy as the band gap energy of the photocatalyst is decomposed and removed.

To The above method makes it possible the plate surface by irradiating the plate surface with light of higher energy as the bandgap energy of the photocatalyst to make hydrophilic. That's because of the effect, that the photocatalyst is made hydrophilic per se. The hydrophilic made surface acts as a non-image area to which a hydrophobic ink does not adhere. A hydrophobic image is produced on the hydrophilic plate surface by using an organic compound by the action of the photocatalyst under irradiation with higher energy light as the bandgap energy of the photocatalyst is decomposed, and is used as an image area, in which the hydrophobic ink is to perform the function as a printing plate adheres.

After this the printing process is finished and the ink is removed from the plate surface was, the organic compound by the action of the photocatalyst by irradiating light with a higher energy than the bandgap energy of the photocatalyst decomposes to the surface, so that the plate surface becomes hydrophilic is done. Consequently, it becomes possible restore the plate in a state that is the condition before making the image area.

According to one further inventive Aspect is that in the above process for producing a printing plate Photocatalyst used a titania photocatalyst.

According to still another inventive Aspect, the hydrophobic image area is made by ejecting an inky liquid, containing the organic compound on the hydrophilic surface of the Plate using an image forming ink jet device.

According to still another inventive Aspect, the hydrophobic image area is made by transfer an ink-like material containing the organic compound the hydrophilic surface the plate using a foil (e.g., a thermal transfer ribbon) on the the ink-like material, the organic compound contains, transferred and a transmission device.

According to still another inventive Aspect is the organic compound used in the above process an organotitanium compound.

According to still another inventive Aspect is the organic compound used in the above process an organosilicon compound.

According to still another inventive Aspect is the compound used in the above method Fatty acid dextrin.

According to the invention further provided a method of reusing a printing plate which was prepared using the method described above, the steps of removing ink from the surface of the Pressure plate after the completion of the printing process and the regeneration the printing plate by converting the surface of the printing plate for hydrophilization by decomposing and removing a hydrophobic image area the printing plate by exposing to light, which has a higher energy as the bandgap energy a photocatalyst, on the surface of the printing plate.

According to the above Reuse methods can the for the regeneration process of the plate required time and cost can be significantly and effectively reduced because the disk surface is easily penetrated Irradiation with light with a higher energy than the band gap energy of the photocatalyst can be regenerated.

According to the invention further provided a printing device comprising a printing drum, which is provided with a hydrophilic plate surface, the one Contains photocatalyst, a plate cleaner that removes the ink from the plate surface, a light irradiation device comprising the plate surface Light irradiated, the higher Energy than the bandgap energy of the photocatalyst, an image forming apparatus having a hydrophobic image area on at least a part of the plate surface by a Organic compound generated by the irradiation of light with a higher one Energy as the band gap energy of the photocatalyst is decomposed and removed, and a dryer, which dries the plate surface, includes.

With the above printing device can the manufacture and regeneration process of the plate using the printing device performed become.

According to one further inventive Aspect are the light irradiation device, the image forming device and the dryer in order to the printing drum with respect to arranged on the rotation direction of the printing drum.

With the above printing device can the production and the regeneration process of the plate continuously with respect to the rotation of the printing drum.

According to still another inventive Aspect is the photocatalyst used in the above printing device a titania photocatalyst.

According to still another inventive Aspect is the image forming apparatus with an ink jet head equipped, which emits an ink-like liquid, the contains the organic photocatalyst and the hydrophobic image area forms on the hydrophilic plate surface.

According to still another inventive Aspect is the image forming apparatus with a film on the the ink-like material containing the organic compound is applied was, and a transmission device, which contains the ink-like material containing the organic compound the hydrophilic plate surface transfers from the foil, and creates the hydrophobic image area on the hydrophilic plate surface, equipped.

According to still another inventive Aspect is the organic compound used in the imaging device is used, an organotitanium compound.

According to still another inventive Aspect is the organic compound used in the imaging device is used, an organosilicon compound.

According to still another inventive Aspect is the organic compound used in the imaging device is used, a fatty acid extrin.

BRIEF DESCRIPTION OF THE DRAWINGS:

Some the features and advantages of the invention have been described, and others will become apparent from the detailed description below and from the accompanying drawings, in which

1 Fig. 12 is a cross-sectional view showing the structure of a printing plate used for a method of manufacturing a printing plate and a reusing method of the printing plate according to an embodiment of the present invention, and showing the hydrophilic property of a coating layer surface;

2 Fig. 16 is a diagram showing an example of an image (an image area) formed on a disk surface and a background (a non-image area);

3A shows a printing plate in the initial state of plate making;

3B shows a state in which the image surface has been formed using an ink jet head on a coating layer;

3C shows a state in which the production of the image area is completed and ready for printing;

4A shows a printing plate in the initial state of plate making;

4B shows a state in which the image area has been formed on the surface of a coating layer using a laser beam;

4C shows a state in which the generation of the image area is completed and ready for printing;

5 Fig. 12 shows a graph for explaining the formation of an image area on a hydrophilic plate surface by using an organic compound and the removal of the image area after completion of a printing operation by irradiation with UV light as a function of time; and

6 is a schematic structural diagram showing an example of the structures of a printing apparatus according to an embodiment of the invention.

DETAILED DESCRIPTION THE INVENTION:

The summarized above and defined by the specified claims Invention is better understood by reference to the following detailed description which with reference to the accompanying drawings should. This detailed description of particularly preferred embodiments, which are given below for the purpose that you build up and the use of certain implementations according to the invention in the Situation is not intended to be limiting as the claims indicated, but should serve as specific examples of this.

1 is a diagram showing a cross-sectional view of the surface of a printing plate according to an embodiment of the invention. In 1 closes the printing plate (P) a base material ( 1 ), an intermediate layer ( 2 ) and a coating layer (printing surface) ( 3 ) one. In this embodiment, the base material is ( 1 ) made of a metal such as aluminum or stainless steel. It should be noted that this is for the base material ( 1 ) is not particularly limited to one metal, and other materials may be used.

The intermediate layer ( 2 ) is on the surface of the base material ( 1 ) educated. Examples of the material used to produce the intermediate layer ( 2 ) can be used include a silicon compound such as silica (SiO ₂ ), a silicone resin and a silicone rubber. Among them, in particular, a silicone resin, alkyd silicone, urethane silicone, epoxysilicone, acrylic silicone, polyester silicone, etc. can be used. The function of the intermediate layer ( 2 ) concludes an improvement in the contact between the base material ( 1 ) and the coating layer ( 3 ) (which will be described later) for ensuring the adhesion of the coating layer ( 3 ) on the base material ( 1 ) one. By placing the intermediate layer ( 2 ) between the base material ( 1 ) and the coating layer ( 3 ), if necessary, it is possible to increase the bond strength of the coating layer ( 3 ) on the base material ( 1 ) to maintain. It should be noted that the intermediate layer ( 2 ) in the case that a sufficient bonding strength of the coating layer ( 3 ) on the base material ( 1 ) can be unnecessary.

The coating layer ( 3 ), which in this embodiment includes titanium oxide as a photocatalyst, is deposited on the intermediate layer ( 2 ) educated. The surface of the coating layer (printing surface) ( 3 ) exhibits a highly hydrophilic property when irradiated with light having a higher energy than the bandgap energy of the photocatalyst, such as UV radiation. This phenomenon occurs due to the properties of the titanium oxide photocatalyst.

In order to maintain the above-mentioned properties or the hydrophilicity or to improve the strength of the coating layer ( 3 ) or the adhesion to the base material ( 1 ) can be added to the coating layer ( 3 ) various additives are added. Examples of such additives include silica compounds such as silica, silica sol, organosilane and a silicone resin, metal oxides of metals such as zirconium and aluminum, and fluorinated resins.

When Titania photocatalyst is a rutile type, an anatase type and a Brooktype known, and any of these titanium oxide photocatalysts can according to the inventive embodiment used alone or in a mixture thereof. As described later It is also preferred that the particle size of the titanium oxide photocatalyst is small in a certain mass. Specifically, it is preferable that the particle size of the titanium oxide photocatalyst is about 0.1 μm or less, hence the photocatalytic function is enhanced by the organic Connections through a photo irradiation process, in which light with a higher one Energy as the band gap energy of the photocatalyst is decomposed. It should be noted that the use of the titanium oxide photocatalyst is suitable according to the invention, in this regard no restriction and also other photocatalysts according to an inventive embodiment can be used in a suitable manner.

Examples for commercial available Titanium oxide photocatalysts in the inventive embodiments can be used include the following: ST-01, ST-21, ST-K01 (a processed Product of the foregoing), ST-K03, STS-01 (a dispersion type), STS-02 and STS-21 (all products of Ishihara Sangyo Kaisha, Ltd.), SSP-25, SSP-20, SSP-M, CSB, CSB-M, LACTI-01 (one type of coating) and LACTI-03-A (products of Sakai Chemical Industry Co., Ltd.); TKS-201, TKS-202, TKC-301 and TKC-302 (products of Tayca Corporation); and PTA, TO and TPX (products of Tanaka Tensha Ltd.).

Further, it is preferable that the thickness of the coating layer is in the range of about 0.01-10 μm. The reason for this is that if the thickness of the coating layer ( 3 ) is too small, it becomes difficult, the above-mentioned properties of the coating layer ( 3 ), and if the thickness of the coating layer is too large, the layer tends to ( 3 ) easily crack and reduce the pressure resistance property. Since the generation of cracks is often observed when the thickness of the coating layer exceeds 20 μm, it is necessary to recognize this thickness of 20 μm as the upper limit even in cases where the above-mentioned range is between about 0.01 and 10 microns is modified. Moreover, it is preferred in practice that the thickness of the coating layer ( 3 ) is in the range between about 0.1 and 3 microns.

As a method for producing the coating layer ( 3 ) may suitably be a sol and an organic titanate method, a vapor deposition method, etc. are selected and applied. When an application method is employed, in addition to the titanium oxide photocatalyst and the above-mentioned various materials, the strength of the coating layer (FIG. 3 ) and the adhesion to the base material ( 1 ), various additives such as solvents, crosslinking agents and surfactants are added to an application liquid. Although the application liquid may be of the ambient drying type or of the heating drying type, the use of the latter type is preferred. The reason for this is that, to increase the strength of the coating layer ( 3 ) is advantageous by heat to improve the pressure resistance properties of the resulting plate.

When next a method of manufacturing the printing plate (P) will be explained.

As in 1 is shown, light having a wavelength with a higher energy than the bandgap energy of the titanium oxide photocatalyst on the surface of the coating layer ( 3 ) so that the entire coating layer ( 3 ), which is the surface of the printing plate (P), becomes a hydrophilic surface having a contact angle with water (W) of about 10 °. This condition is referred to as the "original state of plate making". It should be noted that "light having a wavelength higher in energy than the band gap energy of the titanium oxide photocatalyst" means ultraviolet light having a wavelength of 400 nm or less.

It It should be noted that the term "plate-making" as used herein, the Creation of an image area on a disk surface Basis of digital data using an ink material means that contains an organic compound easily by the action a titanium oxide photocatalyst is decomposed under irradiation with UV light. Furthermore, the means As used herein, "organic Connection "one organic compound with the property that they "by the action of a Photocatalyst under irradiation with light having a higher energy as the bandgap energy of the photocatalyst is decomposed ".

How out 1 can be seen, the surface of the coating layer ( 3 ) is wetted by water (W) in the original state of plate production, ie the hydrophilicity of the coating layer ( 3 ) is originally very high. In other words, it is difficult for the hydrophobic printing ink in the original state of plate-making to be applied to the surface of the coating layer (FIG. 3 ) to be attached.

It It should be noted that the above term "the original state of plate making" is considered may be referred to as the beginning of the actual printing process. More precisely it can be regarded as the state in which digitized data of a given image have already been made and the data ready to write on the plate.

Next, in an image-forming process, an image area ( 4 ) on the surface of the coating layer ( 3 ) in the above state as in 2 shown, produced. The production of the image area ( 4 ) is performed in accordance with digital data concerning the image so as to correspond to the digital data. The image area ( 4 ) is a hydrophobic region whose contact angle with respect to water is about 50 ° or more, preferably 80 ° or more, and hence the hydrophobic printing ink becomes light in the image area (FIG. 4 ), whereas water is difficult to image ( 4 ) is to adhere.

As a method for the preparation of the hydrophobic image area ( 4 1) based on the image data, according to an embodiment of the present invention, the use of a so-called ink-jet method in which an ink-like liquid containing an organic compound is applied to the coating layer (FIG. 3 ) is ejected, suitable.

The 3A to 3C are diagrams showing the production of the image area ( 4 ) by using an ink jet head (ie, an ejection device) ( 6 ) and the concept of plate making after completion of a printing process. In the figures shows 3A a printing plate (P) in its original state of plate making. 3B shows a state in which the image area ( 4 ) on the coating layer ( 3 ) using the ink jet head ( 6 ) was produced. 3C shows the state in which the production of the image area ( 4 ) and finished printing.

As a method for the preparation of the hydrophobic image area ( 4 ) is based on image data, as in the 4A to 4C The use of a so-called layer transfer process, in which a layer ( 7 ) (eg, a thermal transfer ribbon), followed by the above-mentioned, ink-like Material containing an organic compound is applied, and a transmission device ( 8th ), and an ink-like material containing an organic compound on the surface of the hydrophilic coating layer ( 3 ) is transmitted. In this process, the layer ( 7 ) are placed so that they are mixed with the coating layer ( 3 ), an image is printed on the layer ( 7 ) using a laser beam transmitted through the transmission device ( 8th ) is irradiated on the basis of digital data, and the above-mentioned ink-like material containing an organic compound is transferred to the surface of the hydrophilic plate (P). Among the figures showing the concept of forming an image area by the film transfer method is shown 4A the printing plate (P) in its original state of plate making, 4B shows the state in which the image area ( 4 ) on the surface of the coating layer ( 3 ) was produced by using a laser beam, and 4C shows the state in which the production of the image area ( 4 ) and finished printing.

It should be noted that although in the 4A to 4C an embodiment is shown in which the transmission device ( 8th ) a laser beam on the surface of the coating layer ( 3 ), the transmission device ( 8th ) may of course be of another type, such as a thermal head.

As mentioned above, requires the pressure plate (P) according to the inventive embodiment compared to conventional PS plates do not have a process wherein after making a hydrophobic one Area by reaction of photosensitive resins a hydrophilic Area by washing away an unreacted photosensitive Resin is exposed using a developer. consequently can be said that the pressure plate (P) according to the inventive embodiment can be easily used to digitize the printing process.

After completion of the above process, a hydrophobic ink used for printing is applied to the surface of the coating layer (FIG. 3 ) applied. That is, it is made a printing plate, for example, such as in 2 shown. In 2 the shaded area indicates a region in which an image has been formed by an organic compound which has been decomposed by the action of a photocatalyst under irradiation with light having an energy higher than the bandgap energy of the photocatalyst, that is, the region indicates the hydrophobic one Image area ( 4 ) to which the hydrophobic ink is adhered. On the other hand, the blank area, ie the hydrophilic area, identifies the non-image area ( 5 ) from which the hydrophobic ink is repelled and not adhered. In this way, a pattern is generated, and consequently, the surface of the coating layer ( 3 ) can be used as a printing plate. Furthermore, the ink can be mixed with water when a hydrophobic printing ink is applied to the coating layer ( 3 ) is applied. After that, a normal printing process can be performed and completed.

When next is a method of reusing a plate by regeneration according to the plate an inventive embodiment explained.

It It should be noted that the term "regeneration of a disk" means the return of a disk Plate in the state of "original State of plate-making " Transformation of the surface the plate, of which at least some hydrophobic properties and the rest shows hydrophilic properties so that they are complete and evenly becomes hydrophilic.

It is possible to return the printing plate (P) to the original state of plate making by first wiping adhering ink, water, paper dust, etc. from the surface of the coating layer (FIG. 3 and in a subsequent regeneration process, by irradiating light having a higher energy than the bandgap energy of the photocatalyst on the surface of the plate, at least part of which shows hydrophobicity, whereby the organic compound covering the image area ( 4 ), so that the surface of the printing plate (P) is converted into a hydrophilic surface having a contact angle with water (W) of about 10 °. The properties of the plate in which the organic compound present on the plate surface is decomposed and removed, thereby imparting hydrophilicity to the plate by irradiation with light having a higher energy than the photoclastive band gap energy, eg UV light caused by the properties of the titanium oxide photocatalyst used.

As for the kinds of the above-mentioned organic compound, it is preferable to use one which not only reacts or strongly interacts with the hydrophilic portion of the plate surface to obtain a hydrophobic property on the surface, but also easily by the one effect of the titanium oxide photocatalyst can be decomposed under irradiation with UV light.

More accurate is according to an inventive embodiment the use of an organotitanium compound and an organosilicon compound, such as an organosilane compound, is preferred. This one Compounds by reaction with the hydroxyl groups of the titanium oxide photocatalyst on the plate surface to be fixed theoretically a monolayer of hydrophobic Groups on the surface of the titanium oxide photocatalyst produced.

worin (a) die Oberfläche von Titanoxid (hydrophil), (b) eine Organotitanverbindung, (c) die Oberfläche des Titanoxids, die durch Erzeugung einer organischen hydrophoben Gruppe zu Hydrophob umgewandelt wurde, und (d) ein Nebenprodukt ist.A reaction scheme I wherein a tetraalkoxide type organic titanium compound is used as an example of the organotitanium compound is shown below.

wherein (a) the surface of titanium oxide (hydrophilic), (b) an organotitanium compound, (c) the surface of titanium oxide which has been hydrophobically converted to produce an organic hydrophobic group, and (d) a by-product.

worin (a) die Oberfläche des Titanoxids (hydrophil), (b) eine Organosilanverbindung, (c) die Oberfläche des Titanoxids, das durch Erzeugung einer organischen hydrophoben Gruppe zu Hydrophob umgewandelt wurde, und (d) ein Nebenprodukt ist.Further, a reaction scheme II is shown below, wherein a trialkoxy type organic silane is used as an example of the organosilane compound.

wherein (a) the surface of the titanium oxide (hydrophilic), (b) an organosilane compound, (c) the surface of the titanium oxide which has been hydrophobically converted to produce an organic hydrophobic group, and (d) a by-product.

As shown in the above Reaction Schemes I and II, the titanium oxide surface, which has a hydrophilic property due to the presence of hydroxyl groups, is made hydrophobic by the addition of hydrocarbon groups (R, R ₁ and R ₂ ).

It It should be noted that the organotitanium compound is not organic Titanium compounds of the tetraalkoxide type and the organosilane compound (i.e., organosilicone compound) not on trialkoxy type organic silanes limited are.

If these organotitanium compounds or organosilicone compounds used can be, the monolayer of hydrophobic groups rapidly through the Influence of the photocatalyst in combination with the irradiation decomposed with UV light and removed when the plate after the printing process in the original State of plate making is returned and the entire printing surface is thus converted that it is hydrophilic again.

That is, in the example shown in the above Reaction Scheme I, the three alkoxy groups (-OR) bonded to the titanium atom (Ti) derived from the organotitanium compound become carbon dioxide (CO ₂ ) and water (H ₂ O). decomposed and separated from the titanium atom. As a result, only one Ti-O bond remains on the surface of the titanium oxide. Further, as shown in the example in Reaction Scheme II, the alkyl group (-R1) and the alkoxy groups (-O-R2) attached to the silicon atom (Si) derived from the organosilane compound become carbon dioxide (CO2) and Water (H2O) decomposes and from the silicon atom separated. Consequently, only one Si-O bond remains on the surface of the titanium oxide. Since the hydrocarbon chains are thus removed from the surface of the titanium oxide, the surface of the titanium oxide, which is made hydrophobic as shown in (c) in the above Reaction Schemes I and II, in the state shown in Reaction Schemes I and II ( a) and, consequently, the coating layer ( 3 ) made hydrophilic again.

A invention embodiment is because the surface the plate easily by irradiation with, for example, UV light regenerates, effectively reducing the time needed for regeneration the plate is required, as well as to reduce the light energy. Since the monolayer of hydrophobic groups is chemically attached to the surface of the Photocatalyst is implemented, this has the advantage that the Pressure resistance property the plate compared to cases, in which are hydrophobic fats and oils only on the plate surface are applied, becomes very high.

• 1. Alkoxytitan, wie beispielsweise Tetraisopropoxytitan, Tetra-n-butoxytitan und Tetrastearoxytitan;
• 2. Titanacylat, wie beispielsweise Tri-n-butoxytitanacylat und Isopropoxytitantriacylat;
• 3. chelatiertes Titan, wie beispielsweise Diisopropoxytitanbisacetylacetonat und Dihydroxy·Bislactattitan;
• 4. Alkoxysilan, wie beispielsweise Trimethylmethoxysilan, Trimethylethoxysilan, Dimethyldiethoxysilan, Methyltrimethoxysilan, Tetramethoxysilan, Methyltriethoxysilan, Tetraethoxysilan, Methyldimethoxysilan, Octadecyltrimethoxysilan und Octadecyltriethoxysilan;
• 5. Chlorsilan, wie beispielsweise Trimethylchlorsilan, Dimethyldichlorsilan, Methyltrichlorsilan, Methyldichlorsilan und Dimethyldichlorsilan;
• 6. Silan-Kupplungsmittel, wie beispielsweise Vinyltrichlorsilan, Vinyltriethoxysilan, γ-Chlorpropyltrimethoxysilan, γ-Chlorpropylmethyldichlorsilan, γ-Chlorpropylmethyldimethoxysilan, γ-Chlorpropylmethyldiethoxysilan und γ-Aminopropyltriethoxysilan; und
• 7. Fluoralkylsilan, wie beispielsweise Perfluoralkyltrimethoxysilan.

Examples of the organotitanium compounds and organosilane compounds (ie, organosilicone compounds) are listed below in groups 1-3 and 4-7, respectively.

• 1. alkoxytitanium such as tetraisopropoxytitanium, tetra-n-butoxytitanium and tetrastearoxytitanium;
• 2. Titanacylate such as tri-n-butoxytitanium acylate and isopropoxytitanium triacylate;
• 3. chelated titanium such as diisopropoxy titanium bisacetylacetonate and dihydroxy · bislactate titanium;
• 4. alkoxysilane such as trimethylmethoxysilane, trimethylethoxysilane, dimethyldiethoxysilane, methyltrimethoxysilane, tetramethoxysilane, methyltriethoxysilane, tetraethoxysilane, methyldimethoxysilane, octadecyltrimethoxysilane and octadecyltriethoxysilane;
• 5. chlorosilane such as trimethylchlorosilane, dimethyldichlorosilane, methyltrichlorosilane, methyldichlorosilane and dimethyldichlorosilane;
• 6. silane coupling agents such as vinyltrichlorosilane, vinyltriethoxysilane, γ-chloropropyltrimethoxysilane, γ-chloropropylmethyldichlorosilane, γ-chloropropylmethyldimethoxysilane, γ-chloropropylmethyldiethoxysilane and γ-aminopropyltriethoxysilane; and
• 7. Fluoroalkylsilane, such as perfluoroalkyltrimethoxysilane.

It It should be noted that the according to the inventive embodiment usable organic compounds not to the above limited are. About that can out the organic compounds with, for example, a solvent dilute Where necessary, and other additives such as hydrophobic fats and oils and fluorinated compounds be added to the organic compounds.

Further It is preferred as an organic compound that is easily affected by exposure of the titanium oxide photocatalyst decomposed under irradiation with UV light is, fatty acid extrinsic to use. Because fatty acid is strong interacts with the hydroxyl groups of the titanium oxide photocatalyst and on the surface of which is fixed, the image area formed by fatty acid extrinsin stable for a printing process can be used without it being affected by the water, which is used for moistening is substituted.

The Structure of dextrin palmitate, which is an example of the fatty acid extrin, is given below:

Wherein AC ₁₅ H ₃₁ CO- or H, and n denotes the degree of polymerization.

worin (a) die Oberfläche des Titanoxids (hydrophil) ist, (b) ist ein Fettsäuredextrin und (c) ist die Oberfläche des Titanoxids, die durch Erzeugung einer organischen hydrophoben Gruppe zu Hydrophob umgewandelt wurde.Also shown below is an interactive Reaction Scheme III wherein dextrin palmitate is used:

wherein (a) the surface of the titanium oxide is (hydrophilic), (b) is a fatty acid-dextrin and (c) is the surface of the titanium oxide which has been converted to hydrophobic by generation of an organic hydrophobic group.

As shown above, the dextrin palmitate is made only of carbon (C), hydrogen (H) and oxygen (O) is built up to water and decomposes carbon dioxide when irradiated by UV light. Consequently, the use of dextrin palmitate has the advantage that nothing on the surface of the titanium oxide remains after the reaction.

It It should be noted that although in addition to dextrin palmitate the Use of dextrin (palmitate / 2-ethylhexanoate) and dextrin myristate is suitable, the usable in the inventive embodiment fatty acid extrins not limited to this is.

A hydrophobic image area may be formed on the surface of a hydrophilic image plate using an ink-jet method (see 3A to 3C ), wherein an ink-type liquid containing an organotitanium compound, an organosilicone compound, fatty acid-extrin or a solution of these organic compounds, or using the film transfer method (see 4A to 4C In which a layer to which an ink-like material containing these kinds of organic compounds has been applied is placed between the surface of the plate and the transfer device so as to make contact with the plate surface, an image is formed by using a laser beam or a thermal head based on digital data recorded on the layer, and the ink-like material containing the above-mentioned organic compounds is transferred to the hydrophilic plate surface. Further, the subsequent printing process may be started after the image portion formed on the plate surface by the ink-like liquid or the ink-like material containing the organic compound is optionally dried using a drying apparatus.

5 Fig. 12 is a graph for explaining the above-mentioned property of the plate with respect to the contact angle with water. In the in 5 The graph shown plots the time (or duration of operation) on the horizontal axis and the contact angle to water is plotted on the vertical axis. Consequently, in the graph for the printing plate according to the embodiment of the present invention, the change in the contact angle with water (hydrophobic hydrophilic state) is reflected depending on the operation time.

As in the graph in 5 shows the surface of the coating layer ( 3 ) initially has a high hydrophobicity with a contact angle to water of about 10 ° or preferably less than 10 ° by irradiation with UV light, and this is the "original state of plate making" (indicated by the point A in FIG 5 ). Thereafter, a hydrophobic image area is formed on at least a part of the surface of the coating layer (FIG. 3 ), whereby a printing plate is produced by using a method such as the ink jet method or the layer transfer method. Then, as shown by the straight line C in 5 specified, a printing process performed.

After completion of the printing process and removal of deposits and impurities on the coating layer ( 3 ), the image area formed by the above-mentioned organic compound is replaced and removed by irradiation of ultraviolet light, and the surface of the coating layer ( 3 ) is rendered hydrophilic again (indicated by the point A 'in 5 ). That is, the plate is returned to the "original state of plate making" and can be used repeatedly for the printing process.

As mentioned above, has the reuse method for the printing plate according to a invention embodiment the advantage that the reuse process (i.e., the recycling) directly carried out can be. That is, by using a titanium oxide photocatalyst in combination with a technique by which an image area is up Basis of digital data using an ink-like material, which contains an organic compound easily by action of the titanium oxide photocatalyst decomposed under irradiation with UV light is generated, the time required for both the production of the Plate as well for the regeneration of the plate is required to be shortened. Consequently, it becomes possible to carry out the entire printing process very quickly.

When next become concrete inventive embodiments the printing plate and the printing system, by the inventors of present invention are described in detail as follows.

A base material of postcard size aluminum having a thickness of 0.3 mm was prepared, and a primer LAC PR-01 (a product of Sakai Chemical Industry Co., Ltd.) was applied to the base material and dried. The thickness of the primer after drying was 0.8 μm. It should be noted that the primer layer of the intermediate layer ( 2 ) corresponds, as in 1 shown. Thereafter, a titania photocatalyst coating agent LAC TI-01 was applied and dried at 100 ° C, whereby a coating layer ( 3 0.4 μm, containing a titanium oxide photocatalyst.

Then, after irradiation with UV light having a luminance of 40 mW / cm ² on the entire plate surface for 20 seconds using a mercury lamp, the contact angle of the UV-irradiated area with water was measured directly using a CA-W contact angle meter. Type measured. As a result, a measured contact angle of 7 ° was found, and it was confirmed that the area exhibited sufficient hydrophilicity as a non-image area and was in the original state of plate making.

Then became a solution (Liquid (A)), wherein 2 g of tetra-n-butoxytitanium (a product of Nippon Soda Co., Ltd.) in Isoper L (a product from Exxon Chemical Co.) were on the plate surface in the original Condition of plate making using a commercial available Ejected inkjet head, creating dot images with image parts from 10-100% in 10% intervals were prepared and the plate was dried for 5 minutes at 60 ° C, whereby a printing plate was produced. After that, the contact angle became of the image area with an image content of 100% compared to water measured using the CA-W type contact angle meter. When As a result, a measured contact angle of 102 ° was found and it was confirmed that a hydrophobic image area was created and that the area sufficient hydrophobicity as picture area showed.

The so produced plate was in a bank offset printing press New Ace Pro (a product of Alpha Giken Co., Ltd.) assembled and it was set at a printing speed of 3,500 sheets per hour Using the ink HYECOO B Red MZ (a product of Toyo Ink Mfg. Co., Ltd.), water for humidification (Lithofellow 1% solution, a Product of Mitsubishi Heavy Industries, Ltd.) and a sheet of paper (ibest paper) a printing process performed. As a result, the Ink adhered to the areas of the plate where dot images through the liquid (A), whereas the ink is produced in the areas of Do not adhere plate in which no image is generated by the liquid (A) and accordingly dot images were printed on the paper.

Next, an embodiment of the regeneration of the printing plate according to the present invention will be explained. After completion of the printing operation and wiping of ink, water, paper dust, etc. adhering to the plate, UV light having a luminance of 40 mW / cm ^{2 was} irradiated on the entire plate surface for 20 seconds using a mercury lamp. Immediately thereafter, the contact angle of the area where the dot image was present was measured by using the CA-W type contact angle meter. As a result, a measured contact angle of 8 ° was found, and it was confirmed that the area exhibited sufficient hydrophilicity as a non-image area and was in the original state of plate making. As a result, the plate was successfully regenerated.

It should be noted that it is preferable to use a printing machine ( 10 ), as in 6 shown, through management of the above printing process and plate regeneration process. The printing machine ( 10 ) closes a printing drum ( 11 ) located in the center, a plate cleaner ( 12 ), a UV light irradiation device (a light irradiation device) ( 13 ), an imaging device ( 14 ), a dryer ( 15 ), Inking rollers ( 16 ), a dampening water feeder ( 17 ) and a cloth drum ( 18 ) one. The pressure plate (P) (in 6 not shown) is arranged so that it the printing drum ( 11 ).

The plate cleaner ( 12 ) is used to remove ink, wetting water, paper dust, etc. from the coating layer ( 3 ) used after the printing process.

The UV light irradiation device ( 13 ) is used to decompose and remove the organic compounds that 4 ) by irradiation with UV light on the surface of the coating layer ( 3 ) used.

The imaging device ( 14 ) is used to produce a hydrophobic image area ( 4 ) using an ink-like material containing an organic compound which can be decomposed and removed by irradiation with UV light, that is, an organotitanium compound, an organosilicone compound or a fatty acid-extrin. The imaging device ( 14 ) can be configured to match the in 3B shown ink jet head ( 6 ) or the in 4B shown layer ( 7 ) and transmission device ( 8th ), having. That is, the image area ( 4 ) can be produced using the ink jet method or the layer transfer method, whichever is appropriate.

The dryer ( 15 ) is used to vaporize superfluous components, such as volatiles, in the ink-like material surrounding the image area (FIG. 4 ) formed on the coating layer ( 3 ) was applied by drying the coating layer ( 3 ) used.

The UV light irradiation device ( 13 ), the imaging device ( 14 ) and the dryer ( 15 ) are arranged so that they are the printing drum ( 11 ) in this order with respect to the direction of rotation (in 6 indicated by the arrow) of the printing drum ( 11 ) surround.

Consequently, the production and regeneration of the plate can be continuously in conjunction with the rotation of the printing drum ( 11 ), and thus the production and regeneration of the plate can be performed efficiently.

The regeneration process of the plate used for the printing process can be performed as follows using the printing machine ( 10 ) be performed. First, the plate cleaner ( 12 ) in a position in which it is in contact with the printing drum ( 11 ), so that ink, wetting water, paper dust, etc., adhering to the plate, through the plate cleaner ( 12 ) are wiped off the plate. After separation of the plate cleaner ( 12 ) from the printing drum ( 11 ), the entire plate surface is irradiated with UV light emitted from the UV light irradiation device ( 13 ), rendering the plate surface hydrophilic. In this way, the plate is returned to the original state of plate making.

Thereafter, the ink-type material containing an organic compound which can be easily decomposed by the action of the titanium oxide photocatalyst under irradiation of ultraviolet light is obtained by using the image forming apparatus (Fig. 14 ) based on digital data of a previously prepared image on the coating layer ( 3 ) applied. Then the surface of the printing drum ( 11 ), ie the coating layer ( 3 ), if necessary using the dryer ( 15 ) dried. After completion of the above process, the ink supply rollers become 16 ), the dampening water feeder ( 17 ) and cloth drum ( 18 ) in such positions, in which they are in contact with the printing drum ( 11 ) stand. If a piece of paper ( 19 ) in the 6 indicated by the arrow direction under contact with the cloth drum ( 18 ), a continuous printing process is performed.

By using the in 6 shown printing machine ( 10 ), it becomes possible to perform both the plate regeneration process and the printing plate making process wherein the organic compound, which is easily used by the action of the titanium oxide photocatalyst under irradiation with UV light to form the image area, on the same printing machine while the plate is in the printing drum ( 11 ) is mounted state. Consequently, it also becomes possible to run a series of printing processes continuously without stopping the printing machine ( 10 ) or without the need to carry out any problematic exchanges of the plate.

It should be noted that although the plate is arranged to hold the printing drum ( 11 ) in the above-mentioned printing machine ( 10 ), there is no restriction, and, for example, a coating layer ( 3 ) containing a titanium oxide photocatalyst, directly on the surface of the printing drum ( 11 ), ie, a printing drum and a plate can be uniformly manufactured and used according to an embodiment of the present invention.

As explained above It is through the process of making a printing plate, the Reuse procedure for the printing plate and the printing machines according to the inventive embodiments possible, a plate by utilizing the properties of the titanium oxide photocatalyst to regenerate and recycle, i. property of hydrophilization by irradiation with light with an energy that is higher as the bandgap energy of the photocatalyst, and the property of decomposing an organic Materials, in combination with the technique, based on digital data using an ink-like liquid or an ink-like material containing an organic compound contains easily by the action of the titanium oxide photocatalyst under Irradiation with UV light is decomposed, creating an image area becomes. Consequently, the number of plates that can be used after use be significantly reduced, and consequently the costs for the plates are also significantly reduced.

There An image can be generated directly on the plate is the present Invention applicable to the digitization of the printing process, and therefore it becomes possible the time and cost that would be required without digitization, significantly to reduce. About that In addition, compared to conventional ones PS plates no development process required, and therefore will no waste liquid from the development process generated.

There Furthermore, both the plate-making process and the pressure plate regeneration process be performed using the same printing machine can, will it be possible the printing operation immediately perform.

from that can be concluded that according to the process of manufacture a printing plate, the reuse process for the printing plate and the printing machine according to the present invention, the number of plates, which after the Be disposed of by regeneration and recycling of the Plate can be significantly reduced, and therefore also can the price for the plates are significantly reduced. As for the regeneration of a plate In the printing process required time is shortened, can also be used for the preparation needed a printing process Time shortened become. About that In addition, it is made by directly making a plate from digital Data possible, to digitize the printing process, and those required for the printing process Time can be significantly reduced. Furthermore, the plate-making process and the plate regeneration process can be performed while the Plate is left in mounted on the press machine is No plate exchange process is required and therefore the efficiency be further improved.

After this exemplary embodiments of the invention, it will be apparent to those skilled in the art slightly different modifications, Modifications and improvements come to mind. such Modifications, modifications and improvements, although not are explicitly described above, are nonetheless as in the The spirit and scope of the invention are intended and implied. Consequently, the above discussion is to be considered as illustrative only; the invention is only by the following claims and equivalents limited to this and defined.

Claims (23)

A method of making a printing plate comprising the step of: creating a hydrophobic image area ( 4 ) on at least part of a hydrophilic surface ( 3 ) of a plate containing a photocatalyst, wherein the hydrophobic image area ( 4 ) is formed using an organic compound which is decomposed and removed upon irradiation of light having a higher energy than the photocatalytic band gap energy. Process for producing a printing plate according to claim 1, wherein the photocatalyst is a titania photocatalyst. A process for producing a printing plate according to claim 1 or 2, wherein the hydrophobic image portion is formed by releasing an ink-like liquid containing the organic compound onto the hydro phile surface of the plate using an image-forming ink jet device ( 6 ) is formed. A process for producing a printing plate according to claim 1 or 2, wherein the hydrophobic image portion is formed by transferring an ink-like material containing the organic compound to the hydrophilic surface of the plate by using a film to which the ink-type material containing the organic compound was applied, and a transfer device ( 8th ) is formed. Process for producing a printing plate according to claim 1, wherein the organic compound is an organotitanium compound. Process for producing a printing plate according to claim 1, wherein the organic compound is an organosilicon compound is. Process for producing a printing plate according to claim 1, wherein the organic compound is a fatty acid extrin. A method of reusing a printing plate made using the method claimed in claim 1, the method comprising the steps of: removing ink from the surface of the printing plate after completing the printing process; and regenerating the printing plate by converting the surface of the printing plate to hydrophilization by decomposing and removing a hydrophobic image area (US Pat. 4 ) on the printing plate by exposure to light having a higher energy than the bandgap energy of a photocatalyst on the surface of the printing plate. Printing apparatus, comprising: a printing drum ( 11 ) provided with a hydrophilic plate surface containing a photocatalyst; a plate cleaner ( 12 ) removing ink from the disk surface; a light irradiation device ( 13 ) which irradiates the plate surface with light having higher energy than the bandgap energy of the photocatalyst; an image forming apparatus ( 14 ) which forms a hydrophobic image area on at least a part of the disk surface by an organic compound which is decomposed and removed by the irradiation of light having a higher energy than the bandgap energy of the photocatalyst; and a dryer ( 15 ), which dries the plate surface. A printing apparatus according to claim 9, wherein said light irradiation apparatus, the image forming apparatus and the dryer in this order with respect to the printing drum the rotation direction of the printing drum are arranged. Printing apparatus according to claim 9, wherein the photocatalyst is a titania photocatalyst. A printing apparatus according to claim 9 or 10, wherein the image forming apparatus is provided with an ink jet head ( 6 ) which releases an ink-like liquid containing the organic photocatalyst and forms the hydrophobic image area on the hydrophilic plate surface. A printing apparatus according to claim 9 or 10, wherein the image forming apparatus is provided with a film ( 7 ) on which the ink-like material containing the organic compound has been applied, and with a transfer device ( 8th ) which transfers the ink-like material containing the organic compound to the hydrophilic plate surface of the film and creates the hydrophobic image area on the hydrophilic plate surface. Printing device according to claim 9, wherein the organic Compound is an organotitanium compound. Printing device according to claim 9, wherein the organic Compound is an organosilicon compound. Printing device according to claim 9, wherein the organic Compound a fatty acid extrin is. Pressure plate, which comprises: a hydrophilic surface ( 3 ) a plate containing a photocatalyst; and a hydrophobic image area ( 4 ) containing an organic compound present on at least a portion of the hydrophilic surface, wherein the organic compound is decomposed and removed by the irradiation of light having a higher energy than the bandgap energy of the photocatalyst. Pressure plate according to Claim 17, wherein the photocatalyst is a titania photocatalyst is. A printing plate according to claim 17, wherein the hydrophobic image portion is formed by releasing an ink-like liquid containing the organic compound onto the hydrophilic surface of the printing plate using an image-forming ink-jet device ( 6 ) can be generated. A printing plate according to claim 17, wherein the hydrophobic image portion is formed by transferring an ink-like material containing the organic compound to the hydrophilic surface of the printing plate using a film to which the ink-like material containing the organic compound has been applied and a transferring device ( 8th ) can be generated. Pressure plate according to Claim 17, wherein the organic compound is an organotitanium compound is. Pressure plate according to Claim 17, wherein the organic compound is an organosilicon compound is. Pressure plate according to Claim 17, wherein the organic compound is a fatty acid extrin is.